SU1580280A1 - Apparatus for converting pulse duration to voltages - Google Patents

Abstract

The invention relates to a measurement technique and can be used in an automatic stabilization system and in processing frequency signals. The purpose of the invention is to improve the accuracy of conversion. A device for converting a pulse duration to a voltage comprises a first driver, a source of reference voltage, an integrator, a first switch and a latch. The introduction of a second driver, a source of discharge voltage, a comparator, a second and a third switch, allows an increase in the accuracy of the conversion of the pulse duration in the voltage. 1 hp f-ly, 2 ill.

Description

The invention relates to a measurement technique and can be used in automatic stabilization systems in processing frequency feedback signals for converting a pulse duration into a DC voltage.

The aim of the invention is to improve the accuracy of the conversion of the pulse duration into a voltage.

Fig. 1 shows a functional electrical circuit of the device; Fig. 2 shows voltage diagrams characterizing the operation of the device.

The device contains the first driver 1, the second driver 2, the source 3 of the reference voltage, the source 4 of the discharge voltage, the first 5, the second 6 and the third 7 keys, the integrator 8, the comparator 9, the latch

10, while the second driver 2 contains an AND-HE element 11 and the one-oscillator 12, the output of the first driver 1 is connected to the input of the second driver 2, the first output of which is connected to the control input of the second switch 6, the second output - to the control input of the first the key 5, the third output with the control input of the latch 10, the input of which is connected to the output of the integrator 8 and the second input of the comparator 9, the output of which is connected to the control input of the third key 7, and the first input to the inputs of the second and third keys 6 and 7 and the source output 3 exemplary The aprons, the outputs of the five, second 6, and third 7 keys are connected to the first, second, and third inputs of the integrator 8, respectively, and you b.

the source 4 of the discharge voltage is connected to the input of the first switch 5, the input of the driver 2 is its first output and connected to the input of the one-oscillator 12 and the first input of the AND-NE element 11, the output of which is the second output of the second driver 2, and the second the input is connected to the output of the one-shot 12 and is the third output of the second driver 2.

The device works as follows.

rum 10 UBb (6 duration te. The voltage output from the integrator 8, proportional to the period T, according to (1) is recorded and stored by the latch 10. The output voltage of the latch 10 has the form (t). On the negative edge of the signal U ... with in

Odlv

the second driver 2 generates a trigger pulse Us of key 5. The duration of this pulse is equal to t ™ T - T / 2 - t0. When the key 7 5 is closed, the second input of the integrator is connected to the source 4 bit voltage

The electric periodic signal ff does not have an output voltage fj (whose period is measured, is fed to the input of the first shaper 1, the output of which forms rectangular pulses U, (t) with a ratio of 0.5, shown in Fig. 2, 20 which then arrive at the second driver 2, which controls the operation of the keys 5 and 6 and the latch 10. The conductivity of the keys is illustrated in the graphs (Fig. 2) with conventional signals 25 U6 and U5 for keys 6 and 5 and ivy for the latch. the closed position of the keys, low - pa A positive rising edge of 30 U closes the key 6. In this case, a source of 3 reference voltages is connected

m nick

Via key 6 to the integrator 8. The integrator 8 begins to integrate the voltage of the source of the reference voltage 3 + i with a constant time C RC, where R is the resistance between the source of the reference voltage and the integrator sum point, and C is the reference capacitance in the reverse circuit communication of the integrator 8. The key 6 in accordance with the logical operation of the second driver 2 is held in the on state for a time corresponding to half the period T of the input periodic signal. At the same time, over time T / 2, the voltage at the output of the integrator 8 increases to a value equal to

T 1

2

where U0 is the voltage at the start of integration. By the negative difference U, the key 6 is opened, and the integration process is terminated. By the same front U, in the second driver 2, a control signal is formed

and i0 - iet

(one)

50

and u

about. Since the voltages Up and ie have different signs, the integrator discharge starts by law.

U

/

U +

Up | -

R

2)

Where

 R C is constant

integrator.

The value of the resistor R at the second input is selected from the condition Ј «Ь. Given this condition, the discharge process will continue until the integrator restriction circuit 8 comes into effect, consisting of elements 7 and 9. Since the level of the restriction is given by 11e, then the voltage value U0 in (1) will be U0 U3. When the next pulse U is received, the processes 35 will repeat. In view of equalities

U

U,

about - expression in the form of

(1) is represented

U

U9 - U9 5 up (1 - oT) - (W)

2t

T 27

If you choose a condition

1сг

2

RC,

where Tst is the period of the frequency, the value of which is stabilized, then the output

45 the voltage U at the stabilization point T T cr is zero and does not depend on the instability of the voltage when Ј const. Physically, this condition means that the change in voltage at the output of the integrator 8, due to the instability of the voltage of the sample source 3 U and accumulating during the integration process, will be compensated by a change in the initial

its integration conditions are U0 and so that the measurement accuracy is not affected. It should be noted that at the values of T Tst data scheme

U

and u

about. Since the voltages Up and ie have different signs, the integrator discharge starts by law.

U +

Up | -

R

2)

Where

 R C is constant

integrator.

The value of the resistor R at the second input is selected from the condition Ј «Ь. Given this condition, the discharge process will continue until the integrator restriction circuit 8 comes into effect, consisting of elements 7 and 9. Since the level of the restriction is given by 11e, then the voltage value U0 in (1) will be U0 U3. When the next pulse U is received, the processes will repeat. With regard to equality

U

U,

about - expression in the form of

(1) is represented

U

U9 - U9 5 up (1 - oT) - (W)

2t

T 27

If you choose a condition

1сг

2

RC,

where Tst is the period of the frequency, the value of which is stabilized, then the output

the voltage U at the point of stabilization T T cr is zero and does not depend on the instability of the voltage when Ј const. Physically, this condition means that the change in voltage at the output of the integrator 8, due to the instability of the voltage of an exemplary 3 U source and accumulated during the integration process, will be compensated by a change in the initial

integration conditions U0 and so that it will not affect the measurement accuracy. It should be noted that with the values of T TST this scheme

51580280

than known, posAU9 from exemplary ie will cause

ne

l y them with and to l with d

yi - ye (1-) - (i9) (s | g) --AVI- &

However, taking into account that in stabilization systems 0.9 T st 6 T Тот 1.1 Toth

T then the value (I - t) Ј | 0, if, i.e.

.i di§ /,

which is much better than in known systems.

The precision limiting device operates at positive voltages of the integrator and operates as follows.

When the output voltage of the integrator 8 is negative, the comparator 9 is in the first steady state and has a zero voltage output, the key 7 is open and does not affect the operation of the integrator 8. If the output of the integrator 8 is positive polarity but less than Ke, the comparator 9 is still in the first stable position, the key 7 is open and the limiting circuit does not affect the operation of the integrator 8. As soon as the positive output voltage of the integrator 8 exceeds the reference voltage of the circuits the U limits, the comparator 9 switches to the second steady state with a positive output voltage and this will close the key 7, which in turn connects the third input of the integrator 8 to the voltage source (according to the U circuit), which causes the integrator 8 to integrate in the opposite direction Since the voltages U9 and Up have different signs. A prerequisite for the operation of this circuit is b, where R is the input impedance at the third input. Reducing the voltage at the output of the integrator 8 will lead to switching the comparator 9 to the first stable position, disabling the key 7, Under the action of voltage - Up the integrator 8 will be. tend to increase the positive output voltage, however

V

U ,, that will lead to the next

switching comparator 9 and turning on key 7,

Thus, the device allows to convert pulse duration into voltage with a high degree of accuracy, is highly stable and can be used in automatic control systems for processing feedback signals with a primary presentation of information as a periodic signal.

F o

Scope of the Invention 1. An apparatus for converting a pulse width to a voltage comprising a first driver; the source of the reference voltage, the integrator, the first key and the latch, whose input is connected to the output of the integrator, the first input of which is connected to the output of the first key, the input of which is connected to the output of the source of the reference voltage, characterized in that, in order to improve the accuracy of the conversion, it introduced a second converter, a source of discharge voltage, a second and a third key, and a comparator, the output of which is connected to the control input of the third key, whose input is connected to the first input of the comparator,

the output source of the discharge voltage and the input of the second key, the control input of which is connected to the first output of the second driver, and the output to the second input of the integrator, the third input of which is connected to the output of the third key, and the output of the second input of the comparator connected to the input of the second driver, the second output

which is connected to the control input of the first key, and the third output - to the control input of the latch.

2. The device according to claim 1, about tl and - the fact that the second

the driver contains an AND-NOT element and a one-shot, the input of which is the input and the first output of the second driver and is connected to the first input of the AND-NOT element whose output

is the second output of the second driver, and the input is the third output of the second driver and is connected to the second input of the NAND element and the output of the one-shot.

Claims (2)

Claim 1. A device for converting the duration of the pulses into voltage, containing the first driver ^- , ^- 20 reference voltage point, integrator, first switch and latch, the input of which is connected to the output of the integrator, the first input of which is connected to the output of the first switch, the input of which is connected to the output of the reference voltage source, which is related to that, in order to increase the conversion accuracy, a second converter, a discharge voltage source, second and third switches and a comparator are inserted into it, the output of which is connected to the control input of the third key, the input of which is connected to the first input of the comparator, 35 output and the source of the discharge voltage and the input of the second key, the control input of which is connected to the first output of the second driver, and the output to the second input of the integrator, the third input of which is connected to the output of the third key, and the output to the second input of the comparator, the output of the first driver is connected to the input the second driver, the second output 45 of which is connected to the control input of the first key, and the third output with the control input of the latch. 2. The device according to claim 1, about t l and the fact that the second 50, the driver comprises an AND-NOT element and a single-shot, the input of which is the input and the first output of the second driver and connected to the first input of the AND-NOT element, whose output 55 is the second output of the second driver, and the input is the third output of the second driver and connected to the second input element AND NOT and single-output. Figure 2.